sinaps: semiconducting nanowire platform for autonomous sensors

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Semiconducting Nanowire Platform for Autonomous Sensors

SiNAPS

Tyndall National Institute (Coordinator)

Institut für Photonische Technologien e.V

École Polytechnique Fédérale de Lausanne

Imperial College of Science and Technology

Aquamarijn Research BV

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Vision

Project Objectives

Highlights

Impact

Semiconducting Nanowire Platform for Autonomous Sensors

SiNAPS

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ICT and consumer electronics account for approximately 15% of global residential electricity consumption

Data: IEA report (2009)

ICT energy pie grows fast

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4,344 TWh 3,457 TWh 1,038 TWh

Maps: http://en.wikipedia.org

Data: IEA report (2010)

By 2030, energy use by household ICT and consumer electronics will triple consuming 1,700TWh

1,700 TWh in two decades!

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Reduce energy consumption per chip

Eric Pop group

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Harvest ambient energy efficiently

Images http://en.wikipedia.org

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Manage efficiently power at the nano-

and macro-scale

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Utilise resources effectively

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Si

Ge Energy Scavengers

Micro-fluidics

Integrated Sensors

Logics and Transmittance

NW modified

CMOS module

NW modified

CMOS module

CMOS module

I O

A cost-effective technology enabling material platform

Nanotech-based solar energy harvesting (generation II, III PVs)

Energy-efficient ICT

ICT for energy efficiency

SiNAPS response

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Vision

Project Objectives Highlights

Impact

Semiconducting Nanowire Platform for Autonomous Sensors

SiNAPS

S&T1: Nanoscale energy harvesting system based on SiNWs - develop core-shell semiconducting nanowires for efficient light absorption and charge separation - fabricate high-efficiency PV mini-modules

S&T2: Power-efficient, highly-selective/sensitive NW-based chemical sensing - develop surface functionalisation schemes on nanowires for selective binding - demonstrate sensing of streptavidin using immobilised biotin

S&T3: Microfluidics for miniaturised nanowire-based chemical sensor - develop a microfluidic delivery system to be integrated with the chemical nano-sensor.

S&T4: Efficient power management and data processing for micron-sized devices - develop a low-power complete CMOS electronics sensing interface with an embedded energy management concept

S&T5: Integration into a single device of dimensions < 1mm3

- integrate the individual modules into an Autonomous Platform with a target volume at and well beyond the state-of-the-art, namely, 4mm3 and an ultimate target of smaller than 1 mm3.

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Science &Technology objectives

Si Ge

I O

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Vision

Project Objectives

Highlights Impact

Semiconducting Nanowire Platform for Autonomous Sensors

SiNAPS

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properties of a-Si:H from first-principles

log of DOS vs energy (eV) for aSi:H

(12%H)

M. Legesse, M. Nolan and G. Fagas, unpublished

D.V. Lang et al, PRB 25, 5285 (1982)

first-principles

experiment

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miniaturised solar cell with 7.29% efficiency

-1.2 -1.0 -0.8 -0.6 -0.4 -0.2 0.0 0.2 0.4 0.6 0.8 1.0

-30

-20

-10

0

10

20

30

40

50

60

70

80

Curr

ent density (

mA

/cm

2)

Voltage (V)

AM 1.5

DarkContact area: 7.02 mm

2

Efficiency: 7.29%

Open circuit voltage: 476 mV

Current density: 27.03 mA/cm2

Filling factor: 0.562

a b

c d

Guobin Jia, Martin Steglich, Ingo Sill, and Fritz Falk (IPHT), to appear in

Solar Energy Materials and Solar Cells (2011)

500nm

500nm

500nm

500nm

30nm

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PV mini-modules

-1,5 -1,0 -0,5 0,0 0,5 1,0 1,5 2,0 2,5 3,0 3,5-3,0x10

-3

-2,5x10-3

-2,0x10-3

-1,5x10-3

-1,0x10-3

-5,0x10-4

0,0

5,0x10-4

1,0x10-3

Cell 28+29

Cell 28+29+30

Cell 28+29+30+7

Cell 28+29+30+7+8

Cell 28+29+30+7+8+31

Cell 28+29+30+7+8+31+32

Cu

rre

nt

(A)

U (V)VOC= 1.83 V

Active area ≈ 5.9 mm2

Pout >150 µW

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Miniaturised microfluidic delivery

platform

microfluidic platform

microfluidic channel nanowire array

1 x 1 mm

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surface functionalisation demonstrating

biotin-streptavidin binding

XPS-data

attached dye-conjugated streptavidin

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power management electronics

Specification Value and/or Description

Main Chip Size ~ 500µmX700µm excl PADs inc test structures

Mini@sic Chip Area

(including PADs)

1525X1525µm2

Mini@sic Chip Area

(without PADs)

1100X1100µm2

Average Power Consumption

(Power Management)

0.3µW

Average Power Consumption

(Integrated Temperature Sensor)

2µW

Package CLCC 44

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fundamentals of efficient and accurate

simulation tools

M. Iakovidis, GF in preparation

D. Sharma, H. Arefi, GF, submitted

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miniaturisation roadmap & integration

Issue1 Issue2 Issue3

Targets easy experimenting

Targets miniaturization

while maintaining

specifications

Targets miniaturization

while losing minimal

functionality

Test bed helps with proof

of principle

Proof of concept first

SiNAPS Node

Proof of concept second

SiNAPS Node

Chip size 25x25 [mm] Chip size 2x2 [mm] Chip size 1x1 [mm]

Integration based on PCB Integration based on

Polyimide or Ceramic

substrate

Integration based on CMOS

Die

Horizontal Single Substrate

or

Horizontal Multiple

Substrate (depending on

project phase)

Single Substrate with

support for 3D integration

with battery and radio

Single Substrate with

support for 3D integration

with battery and radio

Just intended for R&D

testing

Target Date for Integration

M22

Target Date for Integration

M30

Large Bonding Area

for conductive adhesive

Thin flexfoil Radio chip

test platform

towards issue 2

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Vision

Project Objectives

Highlights

Impact

Semiconducting Nanowire Platform for Autonomous Sensors

SiNAPS

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Innovation pathway

e-Health

Environment and Security

Energy

PV nanomaterial

PV mini-modules

PMU and frontend

co-design

Chemical

nanosensor

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Semiconducting Nanowire Platform for Autonomous Sensors

SiNAPS

Thank you!

the team!